DE4443661A1 - Method for prestressing bolts for connections, and device for carrying them out - Google Patents

Description

The invention relates to a method for prestressing Bolts for connections, which in operation by means of a clamped between a holding part and a stop Power transmission part with tensile forces of adjustable Size, especially columns in Presses for processing plastics, as well as a Device for carrying it out.

EP-A1 0 566 547 (OVAKO) describes a method for Biasing housing bolts known. This is what it is about bolts for housing covers of steam and Gas turbines and of valves for such turbines, which Locations with limited lateral accessibility in Groups and are arranged parallel to each other. This Process works with attaching a Bridge element on the end faces of threaded provided ends of two or more support bolts. Here are the support bolts on opposite sides of the arranged bolt to be preloaded. Biasing this Bolting is then done by a on the bridge element attached hydraulic clamping element.

This procedure is only for a certain arrangement of the Bolt can be used and requires the use of additional ones Bridge elements and hydraulic clamping elements.

The invention has for its object a method for  Preload bolts for connections specified in Operation by means of between a holding part and one Stop clamped power transmission part with Tractive forces of adjustable size can be applied.

The disadvantages mentioned are complex Avoid manipulation with clamping tools by hand.

According to the invention, this object is achieved in that that - a) the connection is made so far that it is resilient to the operating forces that - b) then the Connection by means of the power transmission part with a Tractive force greater than the maximum operating load is charged that - c) then a gap between the Power transmission part and the stop by means of a Filling element is non-positively closed and that finally - d) the load according to b) is lifted again becomes.

It proves to be used for prestressing several in operation bolt loaded at the same time is particularly advantageous, if the burden is only released when the gaps on all bolts are closed. Further preferred embodiments are in the claims featured.

The invention is in the following description and Drawings that illustrate embodiments, closer explained.

Show it:

Fig. 1 is a side view of an injection molding machine for plastic products with feed unit and mold unit Formzustelleinheit,

Fig. 2 shows a partial section of a mold unit and Formzustelleinheit according to Fig. 1,

Fig. 3a shows a partial section of a mold unit of FIG. 2 with an inventive adjustable insert and a non-prestressed column, and

FIG. 3b is a partial section of a mold unit of FIG. 2 with an inventive adjustable insert and a prestressed column.

The injection molding system shown schematically in Fig. 1 comprises a molding unit 1 for use and for holding an injection mold, not shown, a delivery unit 2 for part of the injection mold and a unit 3 for loading the injection mold with material to be sprayed, for. B. with glass fiber-loaded polyester material. The delivery unit 2 comprises four columns or bars, which are subjected to tensile forces of adjustable size, it is therefore also referred to as a plastic press.

In the mold unit 1 , an injection mold, not shown, is attached in an opening 4 . This injection mold consists of two parts, which comprise a cavity for the product to be sprayed. The first part is attached to the side facing the loading unit 3 and has an injection opening for the polyester material. The second part of the injection mold faces the first part and can be brought up to the first part with a hydraulic force in the feed unit 2 in a sealing manner with a compressive force. When the product is finished, the second part of the injection mold is moved back and the finished product is ejected. As described in detail in connection with FIGS. 2 and 3, the first part of the injection mold is fastened on the loading side to a press plate, which in turn is held and clamped on four columns by means of retaining nuts 20 .

The feed unit 3 comprises a filling container 5 for the spray material, to which two sensors 6 , 7 for the filling level are attached. With the aid of a screw conveyor 8 connected to the filling container 5 , the spray material is conveyed into an injection unit 9 . The loading unit 3 is moved up to the injection mold attached in the molding unit 1 for the spraying process on a bed 10 . Subsequently, the molding material is injected by means of an injection piston 11 from the injection unit 9 in the mold.

As shown in FIG. 1, a hydraulic pump 13 driven by an electric motor 12 is provided for driving the movement and conveying members of the loading unit 3 . Feed lines (not shown) lead from this pump 13 to a drive motor 14 for the screw conveyor 8 , to two hydraulic cylinders 15 for the linear drive of the injection piston 11 and to a motor 16 for operating the plasticizing screw of the injection piston 11 .

The partial section of a mold unit and mold feed unit according to FIG. 2 shows a fixed press plate 22 seen from the side, which is fastened to four columns 23 by means of painting nuts 20 (see FIG. 1) against stops 31 on the columns 23 . The columns 23 connect the press plate 22 to a hydraulic cylinder 24 of the mold feed unit, to which they are also fastened with retaining nuts 25 . In the hydraulic cylinder 24 there is a piston 26 which is driven via a feed opening 27 in the hydraulic cylinder 24 . The piston 26 is connected via push rods 28 to a movable press plate 29 which is guided on the columns 23 .

As already indicated in connection with FIG. 1, a part of an injection mold is fastened to the pressure plates 22 and 29 during operation of the injection molding system described so far, but this is not shown. Instead of such an injection mold, FIG. 2 shows an auxiliary block 30 attached to the plate 22 . Through the piston 26 , the connections of the retaining nuts 20 to the columns 23 via the push rods 28 , the plate 29 , the auxiliary block 30 and the plate 22 can be subjected to tensile forces of an adjustable size. The plate 22 is clamped as a force transmission part between the holding nuts 20 as holding parts and the stops 31 on the columns 23 .

Fig. 3a shows a partial section of the fixed plate 22 between a retaining nut 20 and a stop 31 on a column 23 of FIG. 2 in an enlarged representation. It can be seen that the column 23 is passed through a bore 32 in the plate 22 . On the side facing the stop 31, a threaded ring 34 is screwed into a part of the bore 32 provided with thread 33 . The threaded ring 34 engages via a driver 35 in an upstream split ring 36 , through which it is adjustable and non-positively connected to the stop 31 on the column 23 . The split ring 36 has recesses 37 for receiving an adjusting tool.

In Fig. 3a it is assumed that the screw connection between the retaining nuts 20 and the columns 23 is made so far that it can be loaded with the operating forces of the piston 26 according to FIG. 2. Such a screw connection is possible by means of a hand tool via a recess 38 provided for this purpose on the holding nut 20 without substantial expenditure of force. In the partial section corresponding to FIG. 3a according to FIG. 3b, the plate 22 is now subjected to a force greater than the maximum operating load from the piston 26 . As can be seen in particular in FIG. 2, this load results in a tension of the four columns 23 , which is applied by the plate 22 and the hydraulic cylinder 24 to the retaining nuts 20 , 25 .

This tension causes the columns 23 to expand in the area between the end retaining nuts. As FIG. 3b shows, the expansion of the partial area of the column 23 between the stop 31 and the retaining nut 20 between the stop 31 and the upstream split ring 36 creates a gap of the width Δl, which corresponds to a desired prestressing of this partial area of the column 23 . The aforementioned loading of the plate 22 results in such prestresses and gaps evenly on the corresponding subregions of all four columns 23 .

The resulting gaps of width Δl are now closed according to the invention by unscrewing the threaded ring 34 by means of the upstream split ring 36 . As can be seen in FIG. 2, in addition to the four gaps of width .DELTA.l on the plate 22, with the appropriate procedure on the hydraulic cylinder 24 on the other side of the columns 23 , the described pretensioning results in four more such gaps, which are correspondingly, but not in detail shown type can also be closed non-positively. The load on the auxiliary block 30 is then removed again.

This load must be chosen so large that after removal of the above end regions of the columns 23, a preload remains which is greater than the voltage which arises during operation of the press due to the maximum operating load. When such operating loads are applied, the connections between the divided rings 36 and the column stops 31 are relieved, which results in a slight additional expansion of the prestressed column areas. Since this additional elongation is much less than the corresponding operational elongation occurring without prestressing, the prestressed pillar regions, which are subject to a notch effect, such as the threads of the retaining nuts 20 , 25, are stressed much less. This advantage is, in a manner known per se, the reason why preloads on bolts are used.

It is clear to the person skilled in the art that the invention is not restricted to the exemplary embodiments described above. It can be advantageous to use the fixed press plate 22 not as a threaded ring 34 but as a spacer of a suitable preselected thickness in order to avoid a further loaded thread 33 in the bore 32 of the plate 22 . It is even possible to replace the painting nuts 20 , 25 on the columns 23 of the plastic press by threadless holding parts, because the clamping function is taken over by the delivery unit 2 .

Claims (8)

1. A method for prestressing bolts ( 23 ) for connections ( 23 , 20 ) which are subjected to tensile forces of adjustable size during operation by means of a force transmission part ( 22 ) clamped between a holding part ( 20 ) and a stop ( 31 ), in particular by Columns ( 23 ) in presses for processing plastics, characterized in that

• a) the connection ( 23 , 20 ) is made so far that it is resilient to the operating forces that
• b) then the connection ( 23 , 20 ) is loaded by means of the force transmission part ( 22 ) with a tensile force greater than the maximum operating load that
• c) then a gap (Δl) between the power transmission part ( 22 ) and the stop ( 31 ) by means of a filling element ( 34 , 36 ) is closed in a force-locking manner and that finally
• d) the load according to b) is lifted again.

2. The method according to claim 1 for prestressing a plurality of bolts ( 23 ) loaded simultaneously during operation, characterized in that the load according to 1.d) is only lifted again when the gaps (Δl) on all bolts ( 23 ) according to FIG. 1 .c) are closed. 3. The method according to any one of claims 1 or 2 for use in a press for processing plastics, characterized in that the load on the connection ( 23 , 20 ) according to 1.b) via an injection mold and a press plate ( 22 ) as a force transmission part . 4. Device for pretensioning bolts ( 23 ) for connections ( 23 , 20 ) which are subjected to tensile forces of adjustable size during operation by means of a force transmission part ( 22 ) clamped between a holding part ( 20 ) and a stop ( 31 ), in particular by Columns ( 23 ) in presses for processing plastics, characterized by an insert ( 34 , 36 ) which is provided on the force transmission part ( 22 ) on the side facing the stop ( 31 ), in such a way that one during prestressing by means of the force transmission part ( 22 ) resulting gap (Δl) between the power transmission part and the stop can be closed. 5. The device according to claim 4, characterized in that the bolt ( 23 ) is guided through a bore ( 32 ) in the power transmission part ( 22 ) and that the insert ( 34 ) in the power transmission part ( 22 ) as a threaded ring ( 34 ) in the bore ( 32 ) is adjustable. 6. The device according to claim 5, characterized in that the inner diameter of the threaded ring ( 34 ) is larger than the outer diameter of the bolt ( 23 ), that the stop is designed as a shoulder ( 31 ) on the bolt ( 23 ) and that for the non-positive connection between Threaded ring ( 34 ) and shoulder ( 31 ) a split ring ( 36 ) is placed on the bolt ( 23 ). 7. Device according to one of claims 4 to 6 in a press for processing plastics, characterized in that the power transmission part is a press plate ( 22 ) and that an auxiliary block ( 30 ) is provided for prestressing instead of the injection mold. 8. Device according to one of claims 4 to 7 in a press for processing plastics, characterized in that the holding part ( 20 , 25 ) on the bolt ( 23 ) is adjustable by means of a screw connection.